NetBSD/sys/dev/ic/isp_inline.h

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/* $NetBSD: isp_inline.h,v 1.22 2002/10/18 23:32:08 mjacob Exp $ */
/*
* This driver, which is contained in NetBSD in the files:
*
* sys/dev/ic/isp.c
2000-12-23 04:37:57 +03:00
* sys/dev/ic/isp_inline.h
* sys/dev/ic/isp_netbsd.c
* sys/dev/ic/isp_netbsd.h
* sys/dev/ic/isp_target.c
* sys/dev/ic/isp_target.h
* sys/dev/ic/isp_tpublic.h
* sys/dev/ic/ispmbox.h
* sys/dev/ic/ispreg.h
* sys/dev/ic/ispvar.h
* sys/microcode/isp/asm_sbus.h
* sys/microcode/isp/asm_1040.h
* sys/microcode/isp/asm_1080.h
* sys/microcode/isp/asm_12160.h
* sys/microcode/isp/asm_2100.h
* sys/microcode/isp/asm_2200.h
* sys/pci/isp_pci.c
* sys/sbus/isp_sbus.c
*
* Is being actively maintained by Matthew Jacob (mjacob@netbsd.org).
* This driver also is shared source with FreeBSD, OpenBSD, Linux, Solaris,
* Linux versions. This tends to be an interesting maintenance problem.
*
* Please coordinate with Matthew Jacob on changes you wish to make here.
*/
/*
* Copyright (C) 1999 National Aeronautics & Space Administration
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* Qlogic HBA inline functions.
* mjacob@nas.nasa.gov.
*/
#ifndef _ISP_INLINE_H
#define _ISP_INLINE_H
/*
* Handle Functions.
* For each outstanding command there will be a non-zero handle.
* There will be at most isp_maxcmds handles, and isp_lasthdls
* will be a seed for the last handled allocated.
*/
static INLINE int isp_save_xs(struct ispsoftc *, XS_T *, u_int16_t *);
static INLINE XS_T *isp_find_xs(struct ispsoftc *, u_int16_t);
static INLINE u_int16_t isp_find_handle(struct ispsoftc *, XS_T *);
static INLINE int isp_handle_index(u_int16_t);
static INLINE void isp_destroy_handle(struct ispsoftc *, u_int16_t);
static INLINE void isp_remove_handle(struct ispsoftc *, XS_T *);
static INLINE int
isp_save_xs(struct ispsoftc *isp, XS_T *xs, u_int16_t *handlep)
{
int i, j;
for (j = isp->isp_lasthdls, i = 0; i < (int) isp->isp_maxcmds; i++) {
if (isp->isp_xflist[j] == NULL) {
break;
}
if (++j == isp->isp_maxcmds) {
j = 0;
}
}
if (i == isp->isp_maxcmds) {
return (-1);
}
isp->isp_xflist[j] = xs;
*handlep = j+1;
if (++j == isp->isp_maxcmds)
j = 0;
isp->isp_lasthdls = (u_int16_t)j;
return (0);
}
static INLINE XS_T *
isp_find_xs(struct ispsoftc *isp, u_int16_t handle)
{
if (handle < 1 || handle > (u_int16_t) isp->isp_maxcmds) {
return (NULL);
} else {
return (isp->isp_xflist[handle - 1]);
}
}
static INLINE u_int16_t
isp_find_handle(struct ispsoftc *isp, XS_T *xs)
{
int i;
if (xs != NULL) {
for (i = 0; i < isp->isp_maxcmds; i++) {
if (isp->isp_xflist[i] == xs) {
return ((u_int16_t) i+1);
}
}
}
return (0);
}
static INLINE int
isp_handle_index(u_int16_t handle)
{
return (handle-1);
}
static INLINE void
isp_destroy_handle(struct ispsoftc *isp, u_int16_t handle)
{
if (handle > 0 && handle <= (u_int16_t) isp->isp_maxcmds) {
isp->isp_xflist[isp_handle_index(handle)] = NULL;
}
}
static INLINE void
isp_remove_handle(struct ispsoftc *isp, XS_T *xs)
{
isp_destroy_handle(isp, isp_find_handle(isp, xs));
}
static INLINE int
isp_getrqentry(struct ispsoftc *, u_int16_t *, u_int16_t *, void **);
static INLINE int
isp_getrqentry(struct ispsoftc *isp, u_int16_t *iptrp,
u_int16_t *optrp, void **resultp)
{
volatile u_int16_t iptr, optr;
optr = isp->isp_reqodx = READ_REQUEST_QUEUE_OUT_POINTER(isp);
iptr = isp->isp_reqidx;
*resultp = ISP_QUEUE_ENTRY(isp->isp_rquest, iptr);
iptr = ISP_NXT_QENTRY(iptr, RQUEST_QUEUE_LEN(isp));
if (iptr == optr) {
return (1);
}
if (optrp)
*optrp = optr;
if (iptrp)
*iptrp = iptr;
return (0);
}
2000-01-06 05:56:20 +03:00
static INLINE void isp_print_qentry (struct ispsoftc *, char *, int, void *);
2000-01-06 05:56:20 +03:00
#define TBA (4 * (((QENTRY_LEN >> 2) * 3) + 1) + 1)
2000-01-06 05:56:20 +03:00
static INLINE void
isp_print_qentry(struct ispsoftc *isp, char *msg, int idx, void *arg)
2000-01-06 05:56:20 +03:00
{
char buf[TBA];
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int amt, i, j;
u_int8_t *ptr = arg;
isp_prt(isp, ISP_LOGALL, "%s index %d=>", msg, idx);
for (buf[0] = 0, amt = i = 0; i < 4; i++) {
buf[0] = 0;
SNPRINTF(buf, TBA, " ");
2000-01-06 05:56:20 +03:00
for (j = 0; j < (QENTRY_LEN >> 2); j++) {
SNPRINTF(buf, TBA, "%s %02x", buf, ptr[amt++] & 0xff);
}
isp_prt(isp, ISP_LOGALL, buf);
}
}
static INLINE void isp_print_bytes(struct ispsoftc *, char *, int, void *);
static INLINE void
isp_print_bytes(struct ispsoftc *isp, char *msg, int amt, void *arg)
{
char buf[128];
u_int8_t *ptr = arg;
int off;
2000-08-28 01:43:26 +04:00
if (msg)
isp_prt(isp, ISP_LOGALL, "%s:", msg);
off = 0;
2000-08-28 01:43:26 +04:00
buf[0] = 0;
while (off < amt) {
int j, to;
to = off;
for (j = 0; j < 16; j++) {
SNPRINTF(buf, 128, "%s %02x", buf, ptr[off++] & 0xff);
if (off == amt)
break;
2000-01-06 05:56:20 +03:00
}
2000-08-28 01:43:26 +04:00
isp_prt(isp, ISP_LOGALL, "0x%08x:%s", to, buf);
buf[0] = 0;
2000-01-06 05:56:20 +03:00
}
}
/*
* Do the common path to try and ensure that link is up, we've scanned
* the fabric (if we're on a fabric), and that we've synchronized this
* all with our own database and done the appropriate logins.
*
* We repeatedly check for firmware state and loop state after each
* action because things may have changed while we were doing this.
* Any failure or change of state causes us to return a nonzero value.
*
* We honor HBA roles in that if we're not in Initiator mode, we don't
* attempt to sync up the database (that's for somebody else to do,
* if ever).
*
* We assume we enter here with any locks held.
*/
static INLINE int isp_fc_runstate(struct ispsoftc *, int);
static INLINE int
isp_fc_runstate(struct ispsoftc *isp, int tval)
{
fcparam *fcp;
int *tptr;
if (IS_SCSI(isp))
return (0);
tptr = tval? &tval : NULL;
if (isp_control(isp, ISPCTL_FCLINK_TEST, tptr) != 0) {
return (-1);
}
fcp = FCPARAM(isp);
if (fcp->isp_fwstate != FW_READY || fcp->isp_loopstate < LOOP_PDB_RCVD)
return (-1);
if (isp_control(isp, ISPCTL_SCAN_FABRIC, NULL) != 0) {
return (-1);
}
if (isp_control(isp, ISPCTL_SCAN_LOOP, NULL) != 0) {
return (-1);
}
if ((isp->isp_role & ISP_ROLE_INITIATOR) == 0) {
return (0);
}
if (isp_control(isp, ISPCTL_PDB_SYNC, NULL) != 0) {
return (-1);
}
if (fcp->isp_fwstate != FW_READY || fcp->isp_loopstate != LOOP_READY) {
return (-1);
}
return (0);
}
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
/*
* Functions to move stuff to a form that the QLogic RISC engine understands
* and functions to move stuff back to a form the processor understands.
*
* Each platform is required to provide the 8, 16 and 32 bit
* swizzle and unswizzle macros (ISP_IOX{PUT|GET}_{8,16,32})
*
* The assumption is that swizzling and unswizzling is mostly done 'in place'
* (with a few exceptions for efficiency).
*/
static INLINE void isp_copy_out_hdr(struct ispsoftc *, isphdr_t *, isphdr_t *);
static INLINE void isp_copy_in_hdr(struct ispsoftc *, isphdr_t *, isphdr_t *);
static INLINE int isp_get_response_type(struct ispsoftc *, isphdr_t *);
static INLINE void
isp_put_request(struct ispsoftc *, ispreq_t *, ispreq_t *);
static INLINE void
isp_put_request_t2(struct ispsoftc *, ispreqt2_t *, ispreqt2_t *);
static INLINE void
isp_put_request_t3(struct ispsoftc *, ispreqt3_t *, ispreqt3_t *);
static INLINE void
isp_put_extended_request(struct ispsoftc *, ispextreq_t *, ispextreq_t *);
static INLINE void
isp_put_cont_req(struct ispsoftc *, ispcontreq_t *, ispcontreq_t *);
static INLINE void
isp_put_cont64_req(struct ispsoftc *, ispcontreq64_t *, ispcontreq64_t *);
static INLINE void
isp_get_response(struct ispsoftc *, ispstatusreq_t *, ispstatusreq_t *);
static INLINE void
isp_get_response_x(struct ispsoftc *, ispstatus_cont_t *, ispstatus_cont_t *);
static INLINE void
isp_get_rio2(struct ispsoftc *, isp_rio2_t *, isp_rio2_t *);
static INLINE void
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
isp_put_icb(struct ispsoftc *, isp_icb_t *, isp_icb_t *);
static INLINE void
isp_get_pdb(struct ispsoftc *, isp_pdb_t *, isp_pdb_t *);
static INLINE void
isp_get_ct_hdr(struct ispsoftc *isp, ct_hdr_t *, ct_hdr_t *);
static INLINE void
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
isp_put_sns_request(struct ispsoftc *, sns_screq_t *, sns_screq_t *);
static INLINE void
isp_put_gid_ft_request(struct ispsoftc *, sns_gid_ft_req_t *,
sns_gid_ft_req_t *);
static INLINE void
isp_put_gxn_id_request(struct ispsoftc *, sns_gxn_id_req_t *,
sns_gxn_id_req_t *);
static INLINE void
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
isp_get_sns_response(struct ispsoftc *, sns_scrsp_t *, sns_scrsp_t *, int);
static INLINE void
isp_get_gid_ft_response(struct ispsoftc *, sns_gid_ft_rsp_t *,
sns_gid_ft_rsp_t *, int);
static INLINE void
isp_get_gxn_id_response(struct ispsoftc *, sns_gxn_id_rsp_t *,
sns_gxn_id_rsp_t *);
static INLINE void
isp_get_gff_id_response(struct ispsoftc *, sns_gff_id_rsp_t *,
sns_gff_id_rsp_t *);
static INLINE void
isp_get_ga_nxt_response(struct ispsoftc *, sns_ga_nxt_rsp_t *,
sns_ga_nxt_rsp_t *);
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
#ifdef ISP_TARGET_MODE
#ifndef _ISP_TARGET_H
#include "isp_target.h"
#endif
static INLINE void
isp_put_atio(struct ispsoftc *, at_entry_t *, at_entry_t *);
static INLINE void
isp_get_atio(struct ispsoftc *, at_entry_t *, at_entry_t *);
static INLINE void
isp_put_atio2(struct ispsoftc *, at2_entry_t *, at2_entry_t *);
static INLINE void
isp_get_atio2(struct ispsoftc *, at2_entry_t *, at2_entry_t *);
static INLINE void
isp_put_ctio(struct ispsoftc *, ct_entry_t *, ct_entry_t *);
static INLINE void
isp_get_ctio(struct ispsoftc *, ct_entry_t *, ct_entry_t *);
static INLINE void
isp_put_ctio2(struct ispsoftc *, ct2_entry_t *, ct2_entry_t *);
static INLINE void
isp_get_ctio2(struct ispsoftc *, ct2_entry_t *, ct2_entry_t *);
static INLINE void
isp_put_enable_lun(struct ispsoftc *, lun_entry_t *, lun_entry_t *);
static INLINE void
isp_get_enable_lun(struct ispsoftc *, lun_entry_t *, lun_entry_t *);
static INLINE void
isp_put_notify(struct ispsoftc *, in_entry_t *, in_entry_t *);
static INLINE void
isp_get_notify(struct ispsoftc *, in_entry_t *, in_entry_t *);
static INLINE void
isp_put_notify_fc(struct ispsoftc *, in_fcentry_t *, in_fcentry_t *);
static INLINE void
isp_get_notify_fc(struct ispsoftc *, in_fcentry_t *, in_fcentry_t *);
static INLINE void
isp_put_notify_ack(struct ispsoftc *, na_entry_t *, na_entry_t *);
static INLINE void
isp_get_notify_ack(struct ispsoftc *, na_entry_t *, na_entry_t *);
static INLINE void
isp_put_notify_ack_fc(struct ispsoftc *, na_fcentry_t *, na_fcentry_t *);
static INLINE void
isp_get_notify_ack_fc(struct ispsoftc *, na_fcentry_t *, na_fcentry_t *);
#endif
#define ISP_IS_SBUS(isp) \
(ISP_SBUS_SUPPORTED && (isp)->isp_bustype == ISP_BT_SBUS)
/*
* Swizzle/Copy Functions
*/
static INLINE void
isp_copy_out_hdr(struct ispsoftc *isp, isphdr_t *hpsrc, isphdr_t *hpdst)
{
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, hpsrc->rqs_entry_type,
&hpdst->rqs_entry_count);
ISP_IOXPUT_8(isp, hpsrc->rqs_entry_count,
&hpdst->rqs_entry_type);
ISP_IOXPUT_8(isp, hpsrc->rqs_seqno,
&hpdst->rqs_flags);
ISP_IOXPUT_8(isp, hpsrc->rqs_flags,
&hpdst->rqs_seqno);
} else {
ISP_IOXPUT_8(isp, hpsrc->rqs_entry_type,
&hpdst->rqs_entry_type);
ISP_IOXPUT_8(isp, hpsrc->rqs_entry_count,
&hpdst->rqs_entry_count);
ISP_IOXPUT_8(isp, hpsrc->rqs_seqno,
&hpdst->rqs_seqno);
ISP_IOXPUT_8(isp, hpsrc->rqs_flags,
&hpdst->rqs_flags);
}
}
static INLINE void
isp_copy_in_hdr(struct ispsoftc *isp, isphdr_t *hpsrc, isphdr_t *hpdst)
{
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &hpsrc->rqs_entry_type,
hpdst->rqs_entry_count);
ISP_IOXGET_8(isp, &hpsrc->rqs_entry_count,
hpdst->rqs_entry_type);
ISP_IOXGET_8(isp, &hpsrc->rqs_seqno,
hpdst->rqs_flags);
ISP_IOXGET_8(isp, &hpsrc->rqs_flags,
hpdst->rqs_seqno);
} else {
ISP_IOXGET_8(isp, &hpsrc->rqs_entry_type,
hpdst->rqs_entry_type);
ISP_IOXGET_8(isp, &hpsrc->rqs_entry_count,
hpdst->rqs_entry_count);
ISP_IOXGET_8(isp, &hpsrc->rqs_seqno,
hpdst->rqs_seqno);
ISP_IOXGET_8(isp, &hpsrc->rqs_flags,
hpdst->rqs_flags);
}
}
static INLINE int
isp_get_response_type(struct ispsoftc *isp, isphdr_t *hp)
{
u_int8_t type;
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &hp->rqs_entry_count, type);
} else {
ISP_IOXGET_8(isp, &hp->rqs_entry_type, type);
}
return ((int)type);
}
static INLINE void
isp_put_request(struct ispsoftc *isp, ispreq_t *rqsrc, ispreq_t *rqdst)
{
int i;
isp_copy_out_hdr(isp, &rqsrc->req_header, &rqdst->req_header);
ISP_IOXPUT_32(isp, rqsrc->req_handle, &rqdst->req_handle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, rqsrc->req_lun_trn, &rqdst->req_target);
ISP_IOXPUT_8(isp, rqsrc->req_target, &rqdst->req_lun_trn);
} else {
ISP_IOXPUT_8(isp, rqsrc->req_lun_trn, &rqdst->req_lun_trn);
ISP_IOXPUT_8(isp, rqsrc->req_target, &rqdst->req_target);
}
ISP_IOXPUT_16(isp, rqsrc->req_cdblen, &rqdst->req_cdblen);
ISP_IOXPUT_16(isp, rqsrc->req_flags, &rqdst->req_flags);
ISP_IOXPUT_16(isp, rqsrc->req_time, &rqdst->req_time);
ISP_IOXPUT_16(isp, rqsrc->req_seg_count, &rqdst->req_seg_count);
for (i = 0; i < 12; i++) {
ISP_IOXPUT_8(isp, rqsrc->req_cdb[i], &rqdst->req_cdb[i]);
}
for (i = 0; i < ISP_RQDSEG; i++) {
ISP_IOXPUT_32(isp, rqsrc->req_dataseg[i].ds_base,
&rqdst->req_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, rqsrc->req_dataseg[i].ds_count,
&rqdst->req_dataseg[i].ds_count);
}
}
static INLINE void
isp_put_request_t2(struct ispsoftc *isp, ispreqt2_t *tqsrc, ispreqt2_t *tqdst)
{
int i;
isp_copy_out_hdr(isp, &tqsrc->req_header, &tqdst->req_header);
ISP_IOXPUT_32(isp, tqsrc->req_handle, &tqdst->req_handle);
ISP_IOXPUT_8(isp, tqsrc->req_lun_trn, &tqdst->req_lun_trn);
ISP_IOXPUT_8(isp, tqsrc->req_target, &tqdst->req_target);
ISP_IOXPUT_16(isp, tqsrc->req_scclun, &tqdst->req_scclun);
ISP_IOXPUT_16(isp, tqsrc->req_flags, &tqdst->req_flags);
ISP_IOXPUT_16(isp, tqsrc->_res2, &tqdst->_res2);
ISP_IOXPUT_16(isp, tqsrc->req_time, &tqdst->req_time);
ISP_IOXPUT_16(isp, tqsrc->req_seg_count, &tqdst->req_seg_count);
for (i = 0; i < 16; i++) {
ISP_IOXPUT_8(isp, tqsrc->req_cdb[i], &tqdst->req_cdb[i]);
}
ISP_IOXPUT_32(isp, tqsrc->req_totalcnt, &tqdst->req_totalcnt);
for (i = 0; i < ISP_RQDSEG_T2; i++) {
ISP_IOXPUT_32(isp, tqsrc->req_dataseg[i].ds_base,
&tqdst->req_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, tqsrc->req_dataseg[i].ds_count,
&tqdst->req_dataseg[i].ds_count);
}
}
static INLINE void
isp_put_request_t3(struct ispsoftc *isp, ispreqt3_t *tqsrc, ispreqt3_t *tqdst)
{
int i;
isp_copy_out_hdr(isp, &tqsrc->req_header, &tqdst->req_header);
ISP_IOXPUT_32(isp, tqsrc->req_handle, &tqdst->req_handle);
ISP_IOXPUT_8(isp, tqsrc->req_lun_trn, &tqdst->req_lun_trn);
ISP_IOXPUT_8(isp, tqsrc->req_target, &tqdst->req_target);
ISP_IOXPUT_16(isp, tqsrc->req_scclun, &tqdst->req_scclun);
ISP_IOXPUT_16(isp, tqsrc->req_flags, &tqdst->req_flags);
ISP_IOXPUT_16(isp, tqsrc->_res2, &tqdst->_res2);
ISP_IOXPUT_16(isp, tqsrc->req_time, &tqdst->req_time);
ISP_IOXPUT_16(isp, tqsrc->req_seg_count, &tqdst->req_seg_count);
for (i = 0; i < 16; i++) {
ISP_IOXPUT_8(isp, tqsrc->req_cdb[i], &tqdst->req_cdb[i]);
}
ISP_IOXPUT_32(isp, tqsrc->req_totalcnt, &tqdst->req_totalcnt);
for (i = 0; i < ISP_RQDSEG_T3; i++) {
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
ISP_IOXPUT_32(isp, tqsrc->req_dataseg[i].ds_base,
&tqdst->req_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, tqsrc->req_dataseg[i].ds_basehi,
&tqdst->req_dataseg[i].ds_basehi);
ISP_IOXPUT_32(isp, tqsrc->req_dataseg[i].ds_count,
&tqdst->req_dataseg[i].ds_count);
}
}
static INLINE void
isp_put_extended_request(struct ispsoftc *isp, ispextreq_t *xqsrc,
ispextreq_t *xqdst)
{
int i;
isp_copy_out_hdr(isp, &xqsrc->req_header, &xqdst->req_header);
ISP_IOXPUT_32(isp, xqsrc->req_handle, &xqdst->req_handle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, xqsrc->req_lun_trn, &xqdst->req_target);
ISP_IOXPUT_8(isp, xqsrc->req_target, &xqdst->req_lun_trn);
} else {
ISP_IOXPUT_8(isp, xqsrc->req_lun_trn, &xqdst->req_lun_trn);
ISP_IOXPUT_8(isp, xqsrc->req_target, &xqdst->req_target);
}
ISP_IOXPUT_16(isp, xqsrc->req_cdblen, &xqdst->req_cdblen);
ISP_IOXPUT_16(isp, xqsrc->req_flags, &xqdst->req_flags);
ISP_IOXPUT_16(isp, xqsrc->req_time, &xqdst->req_time);
ISP_IOXPUT_16(isp, xqsrc->req_seg_count, &xqdst->req_seg_count);
for (i = 0; i < 44; i++) {
ISP_IOXPUT_8(isp, xqsrc->req_cdb[i], &xqdst->req_cdb[i]);
}
}
static INLINE void
isp_put_cont_req(struct ispsoftc *isp, ispcontreq_t *cqsrc, ispcontreq_t *cqdst)
{
int i;
isp_copy_out_hdr(isp, &cqsrc->req_header, &cqdst->req_header);
for (i = 0; i < ISP_CDSEG; i++) {
ISP_IOXPUT_32(isp, cqsrc->req_dataseg[i].ds_base,
&cqdst->req_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, cqsrc->req_dataseg[i].ds_count,
&cqdst->req_dataseg[i].ds_count);
}
}
static INLINE void
isp_put_cont64_req(struct ispsoftc *isp, ispcontreq64_t *cqsrc,
ispcontreq64_t *cqdst)
{
int i;
isp_copy_out_hdr(isp, &cqsrc->req_header, &cqdst->req_header);
for (i = 0; i < ISP_CDSEG64; i++) {
ISP_IOXPUT_32(isp, cqsrc->req_dataseg[i].ds_base,
&cqdst->req_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, cqsrc->req_dataseg[i].ds_basehi,
&cqdst->req_dataseg[i].ds_basehi);
ISP_IOXPUT_32(isp, cqsrc->req_dataseg[i].ds_count,
&cqdst->req_dataseg[i].ds_count);
}
}
static INLINE void
isp_get_response(struct ispsoftc *isp, ispstatusreq_t *spsrc,
ispstatusreq_t *spdst)
{
int i;
isp_copy_in_hdr(isp, &spsrc->req_header, &spdst->req_header);
ISP_IOXGET_32(isp, &spsrc->req_handle, spdst->req_handle);
ISP_IOXGET_16(isp, &spsrc->req_scsi_status, spdst->req_scsi_status);
ISP_IOXGET_16(isp, &spsrc->req_completion_status,
spdst->req_completion_status);
ISP_IOXGET_16(isp, &spsrc->req_state_flags, spdst->req_state_flags);
ISP_IOXGET_16(isp, &spsrc->req_status_flags, spdst->req_status_flags);
ISP_IOXGET_16(isp, &spsrc->req_time, spdst->req_time);
ISP_IOXGET_16(isp, &spsrc->req_sense_len, spdst->req_sense_len);
ISP_IOXGET_32(isp, &spsrc->req_resid, spdst->req_resid);
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &spsrc->req_response[i],
spdst->req_response[i]);
}
for (i = 0; i < 32; i++) {
ISP_IOXGET_8(isp, &spsrc->req_sense_data[i],
spdst->req_sense_data[i]);
}
}
static INLINE void
isp_get_response_x(struct ispsoftc *isp, ispstatus_cont_t *cpsrc,
ispstatus_cont_t *cpdst)
{
int i;
isp_copy_in_hdr(isp, &cpsrc->req_header, &cpdst->req_header);
for (i = 0; i < 60; i++) {
ISP_IOXGET_8(isp, &cpsrc->req_sense_data[i],
cpdst->req_sense_data[i]);
}
}
static INLINE void
isp_get_rio2(struct ispsoftc *isp, isp_rio2_t *r2src, isp_rio2_t *r2dst)
{
int i;
isp_copy_in_hdr(isp, &r2src->req_header, &r2dst->req_header);
if (r2dst->req_header.rqs_seqno > 30)
r2dst->req_header.rqs_seqno = 30;
for (i = 0; i < r2dst->req_header.rqs_seqno; i++) {
ISP_IOXGET_16(isp, &r2src->req_handles[i],
r2dst->req_handles[i]);
}
while (i < 30) {
r2dst->req_handles[i++] = 0;
}
}
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
static INLINE void
isp_put_icb(struct ispsoftc *isp, isp_icb_t *Is, isp_icb_t *Id)
{
int i;
ISP_SWAP8(Is->icb_version, Is->_reserved0);
ISP_IOXPUT_8(isp, Is->icb_version, &Id->icb_version);
ISP_IOXPUT_8(isp, Is->_reserved0, &Id->_reserved0);
ISP_IOXPUT_16(isp, Is->icb_fwoptions, &Id->icb_fwoptions);
ISP_IOXPUT_16(isp, Is->icb_maxfrmlen, &Id->icb_maxfrmlen);
ISP_IOXPUT_16(isp, Is->icb_maxalloc, &Id->icb_maxalloc);
ISP_IOXPUT_16(isp, Is->icb_execthrottle, &Id->icb_execthrottle);
ISP_SWAP8(Is->icb_retry_count, Is->icb_retry_delay);
ISP_IOXPUT_8(isp, Is->icb_retry_count, &Id->icb_retry_count);
ISP_IOXPUT_8(isp, Is->icb_retry_delay, &Id->icb_retry_delay);
for (i = 0; i < 8; i++) {
ISP_IOXPUT_8(isp, Is->icb_portname[i], &Id->icb_portname[i]);
}
ISP_IOXPUT_16(isp, Is->icb_hardaddr, &Id->icb_hardaddr);
ISP_SWAP8(Is->icb_iqdevtype, Is->icb_logintime);
ISP_IOXPUT_8(isp, Is->icb_iqdevtype, &Id->icb_iqdevtype);
ISP_IOXPUT_8(isp, Is->icb_logintime, &Id->icb_logintime);
for (i = 0; i < 8; i++) {
ISP_IOXPUT_8(isp, Is->icb_nodename[i], &Id->icb_nodename[i]);
}
ISP_IOXPUT_16(isp, Is->icb_rqstout, &Id->icb_rqstout);
ISP_IOXPUT_16(isp, Is->icb_rspnsin, &Id->icb_rspnsin);
ISP_IOXPUT_16(isp, Is->icb_rqstqlen, &Id->icb_rqstqlen);
ISP_IOXPUT_16(isp, Is->icb_rsltqlen, &Id->icb_rsltqlen);
for (i = 0; i < 4; i++) {
ISP_IOXPUT_16(isp, Is->icb_rqstaddr[i], &Id->icb_rqstaddr[i]);
}
for (i = 0; i < 4; i++) {
ISP_IOXPUT_16(isp, Is->icb_respaddr[i], &Id->icb_respaddr[i]);
}
ISP_IOXPUT_16(isp, Is->icb_lunenables, &Id->icb_lunenables);
ISP_SWAP8(Is->icb_ccnt, Is->icb_icnt);
ISP_IOXPUT_8(isp, Is->icb_ccnt, &Id->icb_ccnt);
ISP_IOXPUT_8(isp, Is->icb_icnt, &Id->icb_icnt);
ISP_IOXPUT_16(isp, Is->icb_lunetimeout, &Id->icb_lunetimeout);
ISP_IOXPUT_16(isp, Is->icb_xfwoptions, &Id->icb_xfwoptions);
ISP_SWAP8(Is->icb_racctimer, Is->icb_idelaytimer);
ISP_IOXPUT_8(isp, Is->icb_racctimer, &Id->icb_racctimer);
ISP_IOXPUT_8(isp, Is->icb_idelaytimer, &Id->icb_idelaytimer);
ISP_IOXPUT_16(isp, Is->icb_zfwoptions, &Id->icb_zfwoptions);
}
static INLINE void
isp_get_pdb(struct ispsoftc *isp, isp_pdb_t *src, isp_pdb_t *dst)
{
int i;
ISP_IOXGET_16(isp, &src->pdb_options, dst->pdb_options);
ISP_IOXGET_8(isp, &src->pdb_mstate, dst->pdb_mstate);
ISP_IOXGET_8(isp, &src->pdb_sstate, dst->pdb_sstate);
for (i = 0; i < 4; i++) {
ISP_IOXGET_8(isp, &src->pdb_hardaddr_bits[i],
dst->pdb_hardaddr_bits[i]);
}
for (i = 0; i < 4; i++) {
ISP_IOXGET_8(isp, &src->pdb_portid_bits[i],
dst->pdb_portid_bits[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->pdb_nodename[i], dst->pdb_nodename[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->pdb_portname[i], dst->pdb_portname[i]);
}
ISP_IOXGET_16(isp, &src->pdb_execthrottle, dst->pdb_execthrottle);
ISP_IOXGET_16(isp, &src->pdb_exec_count, dst->pdb_exec_count);
ISP_IOXGET_8(isp, &src->pdb_retry_count, dst->pdb_retry_count);
ISP_IOXGET_8(isp, &src->pdb_retry_delay, dst->pdb_retry_delay);
ISP_IOXGET_16(isp, &src->pdb_resalloc, dst->pdb_resalloc);
ISP_IOXGET_16(isp, &src->pdb_curalloc, dst->pdb_curalloc);
ISP_IOXGET_16(isp, &src->pdb_qhead, dst->pdb_qhead);
ISP_IOXGET_16(isp, &src->pdb_qtail, dst->pdb_qtail);
ISP_IOXGET_16(isp, &src->pdb_tl_next, dst->pdb_tl_next);
ISP_IOXGET_16(isp, &src->pdb_tl_last, dst->pdb_tl_last);
ISP_IOXGET_16(isp, &src->pdb_features, dst->pdb_features);
ISP_IOXGET_16(isp, &src->pdb_pconcurrnt, dst->pdb_pconcurrnt);
ISP_IOXGET_16(isp, &src->pdb_roi, dst->pdb_roi);
ISP_IOXGET_8(isp, &src->pdb_target, dst->pdb_target);
ISP_IOXGET_8(isp, &src->pdb_initiator, dst->pdb_initiator);
ISP_IOXGET_16(isp, &src->pdb_rdsiz, dst->pdb_rdsiz);
ISP_IOXGET_16(isp, &src->pdb_ncseq, dst->pdb_ncseq);
ISP_IOXGET_16(isp, &src->pdb_noseq, dst->pdb_noseq);
ISP_IOXGET_16(isp, &src->pdb_labrtflg, dst->pdb_labrtflg);
ISP_IOXGET_16(isp, &src->pdb_lstopflg, dst->pdb_lstopflg);
ISP_IOXGET_16(isp, &src->pdb_sqhead, dst->pdb_sqhead);
ISP_IOXGET_16(isp, &src->pdb_sqtail, dst->pdb_sqtail);
ISP_IOXGET_16(isp, &src->pdb_ptimer, dst->pdb_ptimer);
ISP_IOXGET_16(isp, &src->pdb_nxt_seqid, dst->pdb_nxt_seqid);
ISP_IOXGET_16(isp, &src->pdb_fcount, dst->pdb_fcount);
ISP_IOXGET_16(isp, &src->pdb_prli_len, dst->pdb_prli_len);
ISP_IOXGET_16(isp, &src->pdb_prli_svc0, dst->pdb_prli_svc0);
ISP_IOXGET_16(isp, &src->pdb_prli_svc3, dst->pdb_prli_svc3);
ISP_IOXGET_16(isp, &src->pdb_loopid, dst->pdb_loopid);
ISP_IOXGET_16(isp, &src->pdb_il_ptr, dst->pdb_il_ptr);
ISP_IOXGET_16(isp, &src->pdb_sl_ptr, dst->pdb_sl_ptr);
}
/*
* CT_HDR canonicalization- only needed for SNS responses
*/
static INLINE void
isp_get_ct_hdr(struct ispsoftc *isp, ct_hdr_t *src, ct_hdr_t *dst)
{
ISP_IOXGET_8(isp, &src->ct_revision, dst->ct_revision);
ISP_IOXGET_8(isp, &src->ct_portid[0], dst->ct_portid[0]);
ISP_IOXGET_8(isp, &src->ct_portid[1], dst->ct_portid[1]);
ISP_IOXGET_8(isp, &src->ct_portid[2], dst->ct_portid[2]);
ISP_IOXGET_8(isp, &src->ct_fcs_type, dst->ct_fcs_type);
ISP_IOXGET_8(isp, &src->ct_fcs_subtype, dst->ct_fcs_subtype);
ISP_IOXGET_8(isp, &src->ct_options, dst->ct_options);
ISP_IOXGET_8(isp, &src->ct_res0, dst->ct_res0);
ISP_IOXGET_16(isp, &src->ct_response, dst->ct_response);
dst->ct_response = (dst->ct_response << 8) | (dst->ct_response >> 8);
ISP_IOXGET_16(isp, &src->ct_resid, dst->ct_resid);
dst->ct_resid = (dst->ct_resid << 8) | (dst->ct_resid >> 8);
ISP_IOXGET_8(isp, &src->ct_res1, dst->ct_res1);
ISP_IOXGET_8(isp, &src->ct_reason, dst->ct_reason);
ISP_IOXGET_8(isp, &src->ct_explanation, dst->ct_explanation);
ISP_IOXGET_8(isp, &src->ct_vunique, dst->ct_vunique);
}
/*
* Generic SNS request - not particularly useful since the per-command data
* isn't always 16 bit words.
*/
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
static INLINE void
isp_put_sns_request(struct ispsoftc *isp, sns_screq_t *src, sns_screq_t *dst)
{
int i, nw = (int) src->snscb_sblen;
ISP_IOXPUT_16(isp, src->snscb_rblen, &dst->snscb_rblen);
for (i = 0; i < 4; i++) {
ISP_IOXPUT_16(isp, src->snscb_addr[i], &dst->snscb_addr[i]);
}
ISP_IOXPUT_16(isp, src->snscb_sblen, &dst->snscb_sblen);
for (i = 0; i < nw; i++) {
ISP_IOXPUT_16(isp, src->snscb_data[i], &dst->snscb_data[i]);
}
}
static INLINE void
isp_put_gid_ft_request(struct ispsoftc *isp, sns_gid_ft_req_t *src,
sns_gid_ft_req_t *dst)
{
ISP_IOXPUT_16(isp, src->snscb_rblen, &dst->snscb_rblen);
ISP_IOXPUT_16(isp, src->snscb_res0, &dst->snscb_res0);
ISP_IOXPUT_16(isp, src->snscb_addr[0], &dst->snscb_addr[0]);
ISP_IOXPUT_16(isp, src->snscb_addr[1], &dst->snscb_addr[1]);
ISP_IOXPUT_16(isp, src->snscb_addr[2], &dst->snscb_addr[2]);
ISP_IOXPUT_16(isp, src->snscb_addr[3], &dst->snscb_addr[3]);
ISP_IOXPUT_16(isp, src->snscb_sblen, &dst->snscb_sblen);
ISP_IOXPUT_16(isp, src->snscb_res1, &dst->snscb_res1);
ISP_IOXPUT_16(isp, src->snscb_cmd, &dst->snscb_cmd);
ISP_IOXPUT_16(isp, src->snscb_mword_div_2, &dst->snscb_mword_div_2);
ISP_IOXPUT_32(isp, src->snscb_res3, &dst->snscb_res3);
ISP_IOXPUT_32(isp, src->snscb_fc4_type, &dst->snscb_fc4_type);
}
static INLINE void
isp_put_gxn_id_request(struct ispsoftc *isp, sns_gxn_id_req_t *src,
sns_gxn_id_req_t *dst)
{
ISP_IOXPUT_16(isp, src->snscb_rblen, &dst->snscb_rblen);
ISP_IOXPUT_16(isp, src->snscb_res0, &dst->snscb_res0);
ISP_IOXPUT_16(isp, src->snscb_addr[0], &dst->snscb_addr[0]);
ISP_IOXPUT_16(isp, src->snscb_addr[1], &dst->snscb_addr[1]);
ISP_IOXPUT_16(isp, src->snscb_addr[2], &dst->snscb_addr[2]);
ISP_IOXPUT_16(isp, src->snscb_addr[3], &dst->snscb_addr[3]);
ISP_IOXPUT_16(isp, src->snscb_sblen, &dst->snscb_sblen);
ISP_IOXPUT_16(isp, src->snscb_res1, &dst->snscb_res1);
ISP_IOXPUT_16(isp, src->snscb_cmd, &dst->snscb_cmd);
ISP_IOXPUT_16(isp, src->snscb_res2, &dst->snscb_res2);
ISP_IOXPUT_32(isp, src->snscb_res3, &dst->snscb_res3);
ISP_IOXPUT_32(isp, src->snscb_portid, &dst->snscb_portid);
}
/*
* Generic SNS response - not particularly useful since the per-command data
* isn't always 16 bit words.
*/
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
static INLINE void
isp_get_sns_response(struct ispsoftc *isp, sns_scrsp_t *src,
sns_scrsp_t *dst, int nwords)
{
int i;
isp_get_ct_hdr(isp, &src->snscb_cthdr, &dst->snscb_cthdr);
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
ISP_IOXGET_8(isp, &src->snscb_port_type, dst->snscb_port_type);
for (i = 0; i < 3; i++) {
ISP_IOXGET_8(isp, &src->snscb_port_id[i],
dst->snscb_port_id[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->snscb_portname[i],
dst->snscb_portname[i]);
}
for (i = 0; i < nwords; i++) {
ISP_IOXGET_16(isp, &src->snscb_data[i], dst->snscb_data[i]);
}
}
static INLINE void
isp_get_gid_ft_response(struct ispsoftc *isp, sns_gid_ft_rsp_t *src,
sns_gid_ft_rsp_t *dst, int nwords)
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
{
int i;
isp_get_ct_hdr(isp, &src->snscb_cthdr, &dst->snscb_cthdr);
for (i = 0; i < nwords; i++) {
int j;
ISP_IOXGET_8(isp,
&src->snscb_ports[i].control,
dst->snscb_ports[i].control);
for (j = 0; j < 3; j++) {
ISP_IOXGET_8(isp,
&src->snscb_ports[i].portid[j],
dst->snscb_ports[i].portid[j]);
}
if (dst->snscb_ports[i].control & 0x80) {
break;
}
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
}
}
static INLINE void
isp_get_gxn_id_response(struct ispsoftc *isp, sns_gxn_id_rsp_t *src,
sns_gxn_id_rsp_t *dst)
{
int i;
isp_get_ct_hdr(isp, &src->snscb_cthdr, &dst->snscb_cthdr);
for (i = 0; i < 8; i++)
ISP_IOXGET_8(isp, &src->snscb_wwn[i], dst->snscb_wwn[i]);
}
static INLINE void
isp_get_gff_id_response(struct ispsoftc *isp, sns_gff_id_rsp_t *src,
sns_gff_id_rsp_t *dst)
{
int i;
isp_get_ct_hdr(isp, &src->snscb_cthdr, &dst->snscb_cthdr);
for (i = 0; i < 32; i++) {
ISP_IOXGET_32(isp, &src->snscb_fc4_features[i],
dst->snscb_fc4_features[i]);
}
}
static INLINE void
isp_get_ga_nxt_response(struct ispsoftc *isp, sns_ga_nxt_rsp_t *src,
sns_ga_nxt_rsp_t *dst)
{
int i;
isp_get_ct_hdr(isp, &src->snscb_cthdr, &dst->snscb_cthdr);
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
ISP_IOXGET_8(isp, &src->snscb_port_type, dst->snscb_port_type);
for (i = 0; i < 3; i++) {
ISP_IOXGET_8(isp, &src->snscb_port_id[i],
dst->snscb_port_id[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->snscb_portname[i],
dst->snscb_portname[i]);
}
ISP_IOXGET_8(isp, &src->snscb_pnlen, dst->snscb_pnlen);
for (i = 0; i < 255; i++) {
ISP_IOXGET_8(isp, &src->snscb_pname[i], dst->snscb_pname[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->snscb_nodename[i],
dst->snscb_nodename[i]);
}
ISP_IOXGET_8(isp, &src->snscb_nnlen, dst->snscb_nnlen);
for (i = 0; i < 255; i++) {
ISP_IOXGET_8(isp, &src->snscb_nname[i], dst->snscb_nname[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->snscb_ipassoc[i],
dst->snscb_ipassoc[i]);
}
for (i = 0; i < 16; i++) {
ISP_IOXGET_8(isp, &src->snscb_ipaddr[i], dst->snscb_ipaddr[i]);
}
for (i = 0; i < 4; i++) {
ISP_IOXGET_8(isp, &src->snscb_svc_class[i],
dst->snscb_svc_class[i]);
}
for (i = 0; i < 32; i++) {
ISP_IOXGET_8(isp, &src->snscb_fc4_types[i],
dst->snscb_fc4_types[i]);
}
for (i = 0; i < 8; i++) {
ISP_IOXGET_8(isp, &src->snscb_fpname[i], dst->snscb_fpname[i]);
}
ISP_IOXGET_8(isp, &src->snscb_reserved, dst->snscb_reserved);
for (i = 0; i < 3; i++) {
ISP_IOXGET_8(isp, &src->snscb_hardaddr[i],
dst->snscb_hardaddr[i]);
}
}
#ifdef ISP_TARGET_MODE
static INLINE void
isp_put_atio(struct ispsoftc *isp, at_entry_t *atsrc, at_entry_t *atdst)
{
int i;
isp_copy_out_hdr(isp, &atsrc->at_header, &atdst->at_header);
ISP_IOXPUT_16(isp, atsrc->at_reserved, &atdst->at_reserved);
ISP_IOXPUT_16(isp, atsrc->at_handle, &atdst->at_handle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, atsrc->at_lun, &atdst->at_iid);
ISP_IOXPUT_8(isp, atsrc->at_iid, &atdst->at_lun);
ISP_IOXPUT_8(isp, atsrc->at_cdblen, &atdst->at_tgt);
ISP_IOXPUT_8(isp, atsrc->at_tgt, &atdst->at_cdblen);
ISP_IOXPUT_8(isp, atsrc->at_status, &atdst->at_scsi_status);
ISP_IOXPUT_8(isp, atsrc->at_scsi_status, &atdst->at_status);
ISP_IOXPUT_8(isp, atsrc->at_tag_val, &atdst->at_tag_type);
ISP_IOXPUT_8(isp, atsrc->at_tag_type, &atdst->at_tag_val);
} else {
ISP_IOXPUT_8(isp, atsrc->at_lun, &atdst->at_lun);
ISP_IOXPUT_8(isp, atsrc->at_iid, &atdst->at_iid);
ISP_IOXPUT_8(isp, atsrc->at_cdblen, &atdst->at_cdblen);
ISP_IOXPUT_8(isp, atsrc->at_tgt, &atdst->at_tgt);
ISP_IOXPUT_8(isp, atsrc->at_status, &atdst->at_status);
ISP_IOXPUT_8(isp, atsrc->at_scsi_status,
&atdst->at_scsi_status);
ISP_IOXPUT_8(isp, atsrc->at_tag_val, &atdst->at_tag_val);
ISP_IOXPUT_8(isp, atsrc->at_tag_type, &atdst->at_tag_type);
}
ISP_IOXPUT_32(isp, atsrc->at_flags, &atdst->at_flags);
for (i = 0; i < ATIO_CDBLEN; i++) {
ISP_IOXPUT_8(isp, atsrc->at_cdb[i], &atdst->at_cdb[i]);
}
for (i = 0; i < QLTM_SENSELEN; i++) {
ISP_IOXPUT_8(isp, atsrc->at_sense[i], &atdst->at_sense[i]);
}
}
static INLINE void
isp_get_atio(struct ispsoftc *isp, at_entry_t *atsrc, at_entry_t *atdst)
{
int i;
isp_copy_in_hdr(isp, &atsrc->at_header, &atdst->at_header);
ISP_IOXGET_16(isp, &atsrc->at_reserved, atdst->at_reserved);
ISP_IOXGET_16(isp, &atsrc->at_handle, atdst->at_handle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &atsrc->at_lun, atdst->at_iid);
ISP_IOXGET_8(isp, &atsrc->at_iid, atdst->at_lun);
ISP_IOXGET_8(isp, &atsrc->at_cdblen, atdst->at_tgt);
ISP_IOXGET_8(isp, &atsrc->at_tgt, atdst->at_cdblen);
ISP_IOXGET_8(isp, &atsrc->at_status, atdst->at_scsi_status);
ISP_IOXGET_8(isp, &atsrc->at_scsi_status, atdst->at_status);
ISP_IOXGET_8(isp, &atsrc->at_tag_val, atdst->at_tag_type);
ISP_IOXGET_8(isp, &atsrc->at_tag_type, atdst->at_tag_val);
} else {
ISP_IOXGET_8(isp, &atsrc->at_lun, atdst->at_lun);
ISP_IOXGET_8(isp, &atsrc->at_iid, atdst->at_iid);
ISP_IOXGET_8(isp, &atsrc->at_cdblen, atdst->at_cdblen);
ISP_IOXGET_8(isp, &atsrc->at_tgt, atdst->at_tgt);
ISP_IOXGET_8(isp, &atsrc->at_status, atdst->at_status);
ISP_IOXGET_8(isp, &atsrc->at_scsi_status,
atdst->at_scsi_status);
ISP_IOXGET_8(isp, &atsrc->at_tag_val, atdst->at_tag_val);
ISP_IOXGET_8(isp, &atsrc->at_tag_type, atdst->at_tag_type);
}
ISP_IOXGET_32(isp, &atsrc->at_flags, atdst->at_flags);
for (i = 0; i < ATIO_CDBLEN; i++) {
ISP_IOXGET_8(isp, &atsrc->at_cdb[i], atdst->at_cdb[i]);
}
for (i = 0; i < QLTM_SENSELEN; i++) {
ISP_IOXGET_8(isp, &atsrc->at_sense[i], atdst->at_sense[i]);
}
}
static INLINE void
isp_put_atio2(struct ispsoftc *isp, at2_entry_t *atsrc, at2_entry_t *atdst)
{
int i;
isp_copy_out_hdr(isp, &atsrc->at_header, &atdst->at_header);
ISP_IOXPUT_32(isp, atsrc->at_reserved, &atdst->at_reserved);
ISP_IOXPUT_8(isp, atsrc->at_lun, &atdst->at_lun);
ISP_IOXPUT_8(isp, atsrc->at_iid, &atdst->at_iid);
ISP_IOXPUT_16(isp, atsrc->at_rxid, &atdst->at_rxid);
ISP_IOXPUT_16(isp, atsrc->at_flags, &atdst->at_flags);
ISP_IOXPUT_16(isp, atsrc->at_status, &atdst->at_status);
ISP_IOXPUT_8(isp, atsrc->at_reserved1, &atdst->at_reserved1);
ISP_IOXPUT_8(isp, atsrc->at_taskcodes, &atdst->at_taskcodes);
ISP_IOXPUT_8(isp, atsrc->at_taskflags, &atdst->at_taskflags);
ISP_IOXPUT_8(isp, atsrc->at_execodes, &atdst->at_execodes);
for (i = 0; i < ATIO2_CDBLEN; i++) {
ISP_IOXPUT_8(isp, atsrc->at_cdb[i], &atdst->at_cdb[i]);
}
ISP_IOXPUT_32(isp, atsrc->at_datalen, &atdst->at_datalen);
ISP_IOXPUT_16(isp, atsrc->at_scclun, &atdst->at_scclun);
for (i = 0; i < 4; i++) {
ISP_IOXPUT_16(isp, atsrc->at_wwpn[i], &atdst->at_wwpn[i]);
}
for (i = 0; i < 6; i++) {
ISP_IOXPUT_16(isp, atsrc->at_reserved2[i],
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
&atdst->at_reserved2[i]);
}
ISP_IOXPUT_16(isp, atsrc->at_oxid, &atdst->at_oxid);
}
static INLINE void
isp_get_atio2(struct ispsoftc *isp, at2_entry_t *atsrc, at2_entry_t *atdst)
{
int i;
isp_copy_in_hdr(isp, &atsrc->at_header, &atdst->at_header);
ISP_IOXGET_32(isp, &atsrc->at_reserved, atdst->at_reserved);
ISP_IOXGET_8(isp, &atsrc->at_lun, atdst->at_lun);
ISP_IOXGET_8(isp, &atsrc->at_iid, atdst->at_iid);
ISP_IOXGET_16(isp, &atsrc->at_rxid, atdst->at_rxid);
ISP_IOXGET_16(isp, &atsrc->at_flags, atdst->at_flags);
ISP_IOXGET_16(isp, &atsrc->at_status, atdst->at_status);
ISP_IOXGET_8(isp, &atsrc->at_reserved1, atdst->at_reserved1);
ISP_IOXGET_8(isp, &atsrc->at_taskcodes, atdst->at_taskcodes);
ISP_IOXGET_8(isp, &atsrc->at_taskflags, atdst->at_taskflags);
ISP_IOXGET_8(isp, &atsrc->at_execodes, atdst->at_execodes);
for (i = 0; i < ATIO2_CDBLEN; i++) {
ISP_IOXGET_8(isp, &atsrc->at_cdb[i], atdst->at_cdb[i]);
}
ISP_IOXGET_32(isp, &atsrc->at_datalen, atdst->at_datalen);
ISP_IOXGET_16(isp, &atsrc->at_scclun, atdst->at_scclun);
for (i = 0; i < 4; i++) {
ISP_IOXGET_16(isp, &atsrc->at_wwpn[i], atdst->at_wwpn[i]);
}
for (i = 0; i < 6; i++) {
ISP_IOXGET_16(isp, &atsrc->at_reserved2[i],
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
atdst->at_reserved2[i]);
}
ISP_IOXGET_16(isp, &atsrc->at_oxid, atdst->at_oxid);
}
static INLINE void
isp_put_ctio(struct ispsoftc *isp, ct_entry_t *ctsrc, ct_entry_t *ctdst)
{
int i;
isp_copy_out_hdr(isp, &ctsrc->ct_header, &ctdst->ct_header);
ISP_IOXPUT_16(isp, ctsrc->ct_reserved, &ctdst->ct_reserved);
ISP_IOXPUT_16(isp, ctsrc->ct_fwhandle, &ctdst->ct_fwhandle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, ctsrc->ct_iid, &ctdst->ct_lun);
ISP_IOXPUT_8(isp, ctsrc->ct_lun, &ctdst->ct_iid);
ISP_IOXPUT_8(isp, ctsrc->ct_tgt, &ctdst->ct_reserved2);
ISP_IOXPUT_8(isp, ctsrc->ct_reserved2, &ctdst->ct_tgt);
ISP_IOXPUT_8(isp, ctsrc->ct_status, &ctdst->ct_scsi_status);
ISP_IOXPUT_8(isp, ctsrc->ct_scsi_status, &ctdst->ct_status);
ISP_IOXPUT_8(isp, ctsrc->ct_tag_type, &ctdst->ct_tag_val);
ISP_IOXPUT_8(isp, ctsrc->ct_tag_val, &ctdst->ct_tag_type);
} else {
ISP_IOXPUT_8(isp, ctsrc->ct_iid, &ctdst->ct_iid);
ISP_IOXPUT_8(isp, ctsrc->ct_lun, &ctdst->ct_lun);
ISP_IOXPUT_8(isp, ctsrc->ct_tgt, &ctdst->ct_tgt);
ISP_IOXPUT_8(isp, ctsrc->ct_reserved2, &ctdst->ct_reserved2);
ISP_IOXPUT_8(isp, ctsrc->ct_scsi_status,
&ctdst->ct_scsi_status);
ISP_IOXPUT_8(isp, ctsrc->ct_status, &ctdst->ct_status);
ISP_IOXPUT_8(isp, ctsrc->ct_tag_type, &ctdst->ct_tag_type);
ISP_IOXPUT_8(isp, ctsrc->ct_tag_val, &ctdst->ct_tag_val);
}
ISP_IOXPUT_32(isp, ctsrc->ct_flags, &ctdst->ct_flags);
ISP_IOXPUT_32(isp, ctsrc->ct_xfrlen, &ctdst->ct_xfrlen);
ISP_IOXPUT_32(isp, ctsrc->ct_resid, &ctdst->ct_resid);
ISP_IOXPUT_16(isp, ctsrc->ct_timeout, &ctdst->ct_timeout);
ISP_IOXPUT_16(isp, ctsrc->ct_seg_count, &ctdst->ct_seg_count);
for (i = 0; i < ISP_RQDSEG; i++) {
ISP_IOXPUT_32(isp, ctsrc->ct_dataseg[i].ds_base,
&ctdst->ct_dataseg[i].ds_base);
ISP_IOXPUT_32(isp, ctsrc->ct_dataseg[i].ds_count,
&ctdst->ct_dataseg[i].ds_count);
}
}
static INLINE void
isp_get_ctio(struct ispsoftc *isp, ct_entry_t *ctsrc, ct_entry_t *ctdst)
{
int i;
isp_copy_in_hdr(isp, &ctsrc->ct_header, &ctdst->ct_header);
ISP_IOXGET_16(isp, &ctsrc->ct_reserved, ctdst->ct_reserved);
ISP_IOXGET_16(isp, &ctsrc->ct_fwhandle, ctdst->ct_fwhandle);
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &ctsrc->ct_lun, ctdst->ct_iid);
ISP_IOXGET_8(isp, &ctsrc->ct_iid, ctdst->ct_lun);
ISP_IOXGET_8(isp, &ctsrc->ct_reserved2, ctdst->ct_tgt);
ISP_IOXGET_8(isp, &ctsrc->ct_tgt, ctdst->ct_reserved2);
ISP_IOXGET_8(isp, &ctsrc->ct_status, ctdst->ct_scsi_status);
ISP_IOXGET_8(isp, &ctsrc->ct_scsi_status, ctdst->ct_status);
ISP_IOXGET_8(isp, &ctsrc->ct_tag_val, ctdst->ct_tag_type);
ISP_IOXGET_8(isp, &ctsrc->ct_tag_type, ctdst->ct_tag_val);
} else {
ISP_IOXGET_8(isp, &ctsrc->ct_lun, ctdst->ct_lun);
ISP_IOXGET_8(isp, &ctsrc->ct_iid, ctdst->ct_iid);
ISP_IOXGET_8(isp, &ctsrc->ct_reserved2, ctdst->ct_reserved2);
ISP_IOXGET_8(isp, &ctsrc->ct_tgt, ctdst->ct_tgt);
ISP_IOXGET_8(isp, &ctsrc->ct_status, ctdst->ct_status);
ISP_IOXGET_8(isp, &ctsrc->ct_scsi_status,
ctdst->ct_scsi_status);
ISP_IOXGET_8(isp, &ctsrc->ct_tag_val, ctdst->ct_tag_val);
ISP_IOXGET_8(isp, &ctsrc->ct_tag_type, ctdst->ct_tag_type);
}
ISP_IOXGET_32(isp, &ctsrc->ct_flags, ctdst->ct_flags);
ISP_IOXGET_32(isp, &ctsrc->ct_xfrlen, ctdst->ct_xfrlen);
ISP_IOXGET_32(isp, &ctsrc->ct_resid, ctdst->ct_resid);
ISP_IOXGET_16(isp, &ctsrc->ct_timeout, ctdst->ct_timeout);
ISP_IOXGET_16(isp, &ctsrc->ct_seg_count, ctdst->ct_seg_count);
for (i = 0; i < ISP_RQDSEG; i++) {
ISP_IOXGET_32(isp,
&ctsrc->ct_dataseg[i].ds_base,
ctdst->ct_dataseg[i].ds_base);
ISP_IOXGET_32(isp,
&ctsrc->ct_dataseg[i].ds_count,
ctdst->ct_dataseg[i].ds_count);
}
}
static INLINE void
isp_put_ctio2(struct ispsoftc *isp, ct2_entry_t *ctsrc, ct2_entry_t *ctdst)
{
int i;
isp_copy_out_hdr(isp, &ctsrc->ct_header, &ctdst->ct_header);
ISP_IOXPUT_16(isp, ctsrc->ct_reserved, &ctdst->ct_reserved);
ISP_IOXPUT_16(isp, ctsrc->ct_fwhandle, &ctdst->ct_fwhandle);
ISP_IOXPUT_8(isp, ctsrc->ct_lun, &ctdst->ct_lun);
ISP_IOXPUT_8(isp, ctsrc->ct_iid, &ctdst->ct_iid);
ISP_IOXPUT_16(isp, ctsrc->ct_rxid, &ctdst->ct_rxid);
ISP_IOXPUT_16(isp, ctsrc->ct_flags, &ctdst->ct_flags);
ISP_IOXPUT_16(isp, ctsrc->ct_timeout, &ctdst->ct_timeout);
ISP_IOXPUT_16(isp, ctsrc->ct_seg_count, &ctdst->ct_seg_count);
ISP_IOXPUT_32(isp, ctsrc->ct_resid, &ctdst->ct_resid);
ISP_IOXPUT_32(isp, ctsrc->ct_reloff, &ctdst->ct_reloff);
Major restructuring for swizzling to the request queue and unswizzling from the response queue. Instead of the ad hoc ISP_SWIZZLE_REQUEST, we now have a complete set of inline functions in isp_inline.h. Each platform is responsible for providing just one of a set of ISP_IOX_{GET,PUT}{8,16,32} macros. The reason this needs to be done is that we need to have a single set of functions that will work correctly on multiple architectures for both little and big endian machines. It also needs to work correctly in the case that we have the request or response queues in memory that has to be treated specially (e.g., have ddi_dma_sync called on it for Solaris after we update it or before we read from it). One thing that falls out of this is that we no longer build requests in the request queue itself. Instead, we build the request locally (e.g., on the stack) and then as part of the swizzling operation, copy it to the request queue entry we've allocated. I thought long and hard about whether this was too expensive a change to make as it in a lot of cases requires an extra copy. On balance, the flexbility is worth it. With any luck, the entry that we build locally stays in a processor writeback cache (after all, it's only 64 bytes) so that the cost of actually flushing it to the memory area that is the shared queue with the PCI device is not all that expensive. We may examine this again and try to get clever in the future to try and avoid copies. Another change that falls out of this is that MEMORYBARRIER should be taken a lot more seriously. The macro ISP_ADD_REQUEST does a MEMORYBARRIER on the entry being added. But there had been many other places this had been missing. It's now very important that it be done. For NetBSD, it does a ddi_dmamap_sync as appropriate. This gets us out of the explicit ddi_dmamap_sync on the whole response queue that we did for SBus cards at each interrupt. Set things up so that platforms that cannot have an SBus don't get a lot of the SBus code checks (dead coded out). Additional changes: Fix a longstanding buglet of sorts. When we get an entry via isp_getrqentry, the iptr value that gets returned is the value we intend to eventually plug into the ISP registers as the entry *one past* the last one we've written- *not* the current entry we're updating. All along we've been calling sync functions on the wrong index value. Argh. The 'fix' here is to rename all 'iptr' variables as 'nxti' to remember that this is the 'next' pointer- not the current pointer. Devote a single bit to mboxbsy- and set aside bits for output mbox registers that we need to pick up- we can have at least one command which does not have any defined output registers (MBOX_EXECUTE_FIRMWARE). Explicitly decode GetAllNext SNS Response back *as* a GetAllNext response. Otherwise, we won't unswizzle it correctly. Nuke some additional __P macros.
2001-12-14 03:13:44 +03:00
if ((ctsrc->ct_flags & CT2_FLAG_MMASK) == CT2_FLAG_MODE0) {
ISP_IOXPUT_32(isp, ctsrc->rsp.m0._reserved,
&ctdst->rsp.m0._reserved);
ISP_IOXPUT_16(isp, ctsrc->rsp.m0._reserved2,
&ctdst->rsp.m0._reserved2);
ISP_IOXPUT_16(isp, ctsrc->rsp.m0.ct_scsi_status,
&ctdst->rsp.m0.ct_scsi_status);
ISP_IOXPUT_32(isp, ctsrc->rsp.m0.ct_xfrlen,
&ctdst->rsp.m0.ct_xfrlen);
if (ctsrc->ct_header.rqs_entry_type == RQSTYPE_CTIO2) {
for (i = 0; i < ISP_RQDSEG_T2; i++) {
ISP_IOXPUT_32(isp,
ctsrc->rsp.m0.ct_dataseg[i].ds_base,
&ctdst->rsp.m0.ct_dataseg[i].ds_base);
ISP_IOXPUT_32(isp,
ctsrc->rsp.m0.ct_dataseg[i].ds_count,
&ctdst->rsp.m0.ct_dataseg[i].ds_count);
}
} else if (ctsrc->ct_header.rqs_entry_type == RQSTYPE_CTIO3) {
for (i = 0; i < ISP_RQDSEG_T3; i++) {
ISP_IOXPUT_32(isp,
ctsrc->rsp.m0.ct_dataseg64[i].ds_base,
&ctdst->rsp.m0.ct_dataseg64[i].ds_base);
ISP_IOXPUT_32(isp,
ctsrc->rsp.m0.ct_dataseg64[i].ds_basehi,
&ctdst->rsp.m0.ct_dataseg64[i].ds_basehi);
ISP_IOXPUT_32(isp,
ctsrc->rsp.m0.ct_dataseg64[i].ds_count,
&ctdst->rsp.m0.ct_dataseg64[i].ds_count);
}
} else if (ctsrc->ct_header.rqs_entry_type == RQSTYPE_CTIO4) {
ISP_IOXPUT_16(isp, ctsrc->rsp.m0.ct_dslist.ds_type,
&ctdst->rsp.m0.ct_dslist.ds_type);
ISP_IOXPUT_32(isp, ctsrc->rsp.m0.ct_dslist.ds_segment,
&ctdst->rsp.m0.ct_dslist.ds_segment);
ISP_IOXPUT_32(isp, ctsrc->rsp.m0.ct_dslist.ds_base,
&ctdst->rsp.m0.ct_dslist.ds_base);
}
} else if ((ctsrc->ct_flags & CT2_FLAG_MMASK) == CT2_FLAG_MODE1) {
ISP_IOXPUT_16(isp, ctsrc->rsp.m1._reserved,
&ctdst->rsp.m1._reserved);
ISP_IOXPUT_16(isp, ctsrc->rsp.m1._reserved2,
&ctdst->rsp.m1._reserved2);
ISP_IOXPUT_16(isp, ctsrc->rsp.m1.ct_senselen,
&ctdst->rsp.m1.ct_senselen);
ISP_IOXPUT_16(isp, ctsrc->rsp.m1.ct_scsi_status,
&ctdst->rsp.m1.ct_scsi_status);
ISP_IOXPUT_16(isp, ctsrc->rsp.m1.ct_resplen,
&ctdst->rsp.m1.ct_resplen);
for (i = 0; i < MAXRESPLEN; i++) {
ISP_IOXPUT_8(isp, ctsrc->rsp.m1.ct_resp[i],
&ctdst->rsp.m1.ct_resp[i]);
}
} else {
ISP_IOXPUT_32(isp, ctsrc->rsp.m2._reserved,
&ctdst->rsp.m2._reserved);
ISP_IOXPUT_16(isp, ctsrc->rsp.m2._reserved2,
&ctdst->rsp.m2._reserved2);
ISP_IOXPUT_16(isp, ctsrc->rsp.m2._reserved3,
&ctdst->rsp.m2._reserved3);
ISP_IOXPUT_32(isp, ctsrc->rsp.m2.ct_datalen,
&ctdst->rsp.m2.ct_datalen);
ISP_IOXPUT_32(isp, ctsrc->rsp.m2.ct_fcp_rsp_iudata.ds_base,
&ctdst->rsp.m2.ct_fcp_rsp_iudata.ds_base);
ISP_IOXPUT_32(isp, ctsrc->rsp.m2.ct_fcp_rsp_iudata.ds_count,
&ctdst->rsp.m2.ct_fcp_rsp_iudata.ds_count);
}
}
static INLINE void
isp_get_ctio2(struct ispsoftc *isp, ct2_entry_t *ctsrc, ct2_entry_t *ctdst)
{
int i;
isp_copy_in_hdr(isp, &ctsrc->ct_header, &ctdst->ct_header);
ISP_IOXGET_16(isp, &ctsrc->ct_reserved, ctdst->ct_reserved);
ISP_IOXGET_16(isp, &ctsrc->ct_fwhandle, ctdst->ct_fwhandle);
ISP_IOXGET_8(isp, &ctsrc->ct_lun, ctdst->ct_lun);
ISP_IOXGET_8(isp, &ctsrc->ct_iid, ctdst->ct_iid);
ISP_IOXGET_16(isp, &ctsrc->ct_rxid, ctdst->ct_rxid);
ISP_IOXGET_16(isp, &ctsrc->ct_flags, ctdst->ct_flags);
ISP_IOXGET_16(isp, &ctsrc->ct_status, ctdst->ct_status);
ISP_IOXGET_16(isp, &ctsrc->ct_timeout, ctdst->ct_timeout);
ISP_IOXGET_16(isp, &ctsrc->ct_seg_count, ctdst->ct_seg_count);
ISP_IOXGET_32(isp, &ctsrc->ct_reloff, ctdst->ct_reloff);
ISP_IOXGET_32(isp, &ctsrc->ct_resid, ctdst->ct_resid);
for (i = 0; i < 4; i++) {
ISP_IOXGET_32(isp, &ctsrc->rsp.fw._reserved[i],
ctdst->rsp.fw._reserved[i]);
}
ISP_IOXGET_16(isp, &ctsrc->rsp.fw.ct_scsi_status,
ctdst->rsp.fw.ct_scsi_status);
for (i = 0; i < QLTM_SENSELEN; i++) {
ISP_IOXGET_8(isp, &ctsrc->rsp.fw.ct_sense[i],
ctdst->rsp.fw.ct_sense[i]);
}
}
static INLINE void
isp_put_enable_lun(struct ispsoftc *isp, lun_entry_t *lesrc, lun_entry_t *ledst)
{
int i;
isp_copy_out_hdr(isp, &lesrc->le_header, &ledst->le_header);
ISP_IOXPUT_32(isp, lesrc->le_reserved, &ledst->le_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, lesrc->le_lun, &ledst->le_rsvd);
ISP_IOXPUT_8(isp, lesrc->le_rsvd, &ledst->le_lun);
ISP_IOXPUT_8(isp, lesrc->le_ops, &ledst->le_tgt);
ISP_IOXPUT_8(isp, lesrc->le_tgt, &ledst->le_ops);
ISP_IOXPUT_8(isp, lesrc->le_status, &ledst->le_reserved2);
ISP_IOXPUT_8(isp, lesrc->le_reserved2, &ledst->le_status);
ISP_IOXPUT_8(isp, lesrc->le_cmd_count, &ledst->le_in_count);
ISP_IOXPUT_8(isp, lesrc->le_in_count, &ledst->le_cmd_count);
ISP_IOXPUT_8(isp, lesrc->le_cdb6len, &ledst->le_cdb7len);
ISP_IOXPUT_8(isp, lesrc->le_cdb7len, &ledst->le_cdb6len);
} else {
ISP_IOXPUT_8(isp, lesrc->le_lun, &ledst->le_lun);
ISP_IOXPUT_8(isp, lesrc->le_rsvd, &ledst->le_rsvd);
ISP_IOXPUT_8(isp, lesrc->le_ops, &ledst->le_ops);
ISP_IOXPUT_8(isp, lesrc->le_tgt, &ledst->le_tgt);
ISP_IOXPUT_8(isp, lesrc->le_status, &ledst->le_status);
ISP_IOXPUT_8(isp, lesrc->le_reserved2, &ledst->le_reserved2);
ISP_IOXPUT_8(isp, lesrc->le_cmd_count, &ledst->le_cmd_count);
ISP_IOXPUT_8(isp, lesrc->le_in_count, &ledst->le_in_count);
ISP_IOXPUT_8(isp, lesrc->le_cdb6len, &ledst->le_cdb6len);
ISP_IOXPUT_8(isp, lesrc->le_cdb7len, &ledst->le_cdb7len);
}
ISP_IOXPUT_32(isp, lesrc->le_flags, &ledst->le_flags);
ISP_IOXPUT_16(isp, lesrc->le_timeout, &ledst->le_timeout);
for (i = 0; i < 20; i++) {
ISP_IOXPUT_8(isp, lesrc->le_reserved3[i],
&ledst->le_reserved3[i]);
}
}
static INLINE void
isp_get_enable_lun(struct ispsoftc *isp, lun_entry_t *lesrc, lun_entry_t *ledst)
{
int i;
isp_copy_in_hdr(isp, &lesrc->le_header, &ledst->le_header);
ISP_IOXGET_32(isp, &lesrc->le_reserved, ledst->le_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &lesrc->le_lun, ledst->le_rsvd);
ISP_IOXGET_8(isp, &lesrc->le_rsvd, ledst->le_lun);
ISP_IOXGET_8(isp, &lesrc->le_ops, ledst->le_tgt);
ISP_IOXGET_8(isp, &lesrc->le_tgt, ledst->le_ops);
ISP_IOXGET_8(isp, &lesrc->le_status, ledst->le_reserved2);
ISP_IOXGET_8(isp, &lesrc->le_reserved2, ledst->le_status);
ISP_IOXGET_8(isp, &lesrc->le_cmd_count, ledst->le_in_count);
ISP_IOXGET_8(isp, &lesrc->le_in_count, ledst->le_cmd_count);
ISP_IOXGET_8(isp, &lesrc->le_cdb6len, ledst->le_cdb7len);
ISP_IOXGET_8(isp, &lesrc->le_cdb7len, ledst->le_cdb6len);
} else {
ISP_IOXGET_8(isp, &lesrc->le_lun, ledst->le_lun);
ISP_IOXGET_8(isp, &lesrc->le_rsvd, ledst->le_rsvd);
ISP_IOXGET_8(isp, &lesrc->le_ops, ledst->le_ops);
ISP_IOXGET_8(isp, &lesrc->le_tgt, ledst->le_tgt);
ISP_IOXGET_8(isp, &lesrc->le_status, ledst->le_status);
ISP_IOXGET_8(isp, &lesrc->le_reserved2, ledst->le_reserved2);
ISP_IOXGET_8(isp, &lesrc->le_cmd_count, ledst->le_cmd_count);
ISP_IOXGET_8(isp, &lesrc->le_in_count, ledst->le_in_count);
ISP_IOXGET_8(isp, &lesrc->le_cdb6len, ledst->le_cdb6len);
ISP_IOXGET_8(isp, &lesrc->le_cdb7len, ledst->le_cdb7len);
}
ISP_IOXGET_32(isp, &lesrc->le_flags, ledst->le_flags);
ISP_IOXGET_16(isp, &lesrc->le_timeout, ledst->le_timeout);
for (i = 0; i < 20; i++) {
ISP_IOXGET_8(isp, &lesrc->le_reserved3[i],
ledst->le_reserved3[i]);
}
}
static INLINE void
isp_put_notify(struct ispsoftc *isp, in_entry_t *insrc, in_entry_t *indst)
{
int i;
isp_copy_out_hdr(isp, &insrc->in_header, &indst->in_header);
ISP_IOXPUT_32(isp, insrc->in_reserved, &indst->in_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, insrc->in_lun, &indst->in_iid);
ISP_IOXPUT_8(isp, insrc->in_iid, &indst->in_lun);
ISP_IOXPUT_8(isp, insrc->in_reserved2, &indst->in_tgt);
ISP_IOXPUT_8(isp, insrc->in_tgt, &indst->in_reserved2);
ISP_IOXPUT_8(isp, insrc->in_status, &indst->in_rsvd2);
ISP_IOXPUT_8(isp, insrc->in_rsvd2, &indst->in_status);
ISP_IOXPUT_8(isp, insrc->in_tag_val, &indst->in_tag_type);
ISP_IOXPUT_8(isp, insrc->in_tag_type, &indst->in_tag_val);
} else {
ISP_IOXPUT_8(isp, insrc->in_lun, &indst->in_lun);
ISP_IOXPUT_8(isp, insrc->in_iid, &indst->in_iid);
ISP_IOXPUT_8(isp, insrc->in_reserved2, &indst->in_reserved2);
ISP_IOXPUT_8(isp, insrc->in_tgt, &indst->in_tgt);
ISP_IOXPUT_8(isp, insrc->in_status, &indst->in_status);
ISP_IOXPUT_8(isp, insrc->in_rsvd2, &indst->in_rsvd2);
ISP_IOXPUT_8(isp, insrc->in_tag_val, &indst->in_tag_val);
ISP_IOXPUT_8(isp, insrc->in_tag_type, &indst->in_tag_type);
}
ISP_IOXPUT_32(isp, insrc->in_flags, &indst->in_flags);
ISP_IOXPUT_16(isp, insrc->in_seqid, &indst->in_seqid);
for (i = 0; i < IN_MSGLEN; i++) {
ISP_IOXPUT_8(isp, insrc->in_msg[i], &indst->in_msg[i]);
}
for (i = 0; i < IN_RSVDLEN; i++) {
ISP_IOXPUT_8(isp, insrc->in_reserved3[i],
&indst->in_reserved3[i]);
}
for (i = 0; i < QLTM_SENSELEN; i++) {
ISP_IOXPUT_8(isp, insrc->in_sense[i],
&indst->in_sense[i]);
}
}
static INLINE void
isp_get_notify(struct ispsoftc *isp, in_entry_t *insrc, in_entry_t *indst)
{
int i;
isp_copy_in_hdr(isp, &insrc->in_header, &indst->in_header);
ISP_IOXGET_32(isp, &insrc->in_reserved, indst->in_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &insrc->in_lun, indst->in_iid);
ISP_IOXGET_8(isp, &insrc->in_iid, indst->in_lun);
ISP_IOXGET_8(isp, &insrc->in_reserved2, indst->in_tgt);
ISP_IOXGET_8(isp, &insrc->in_tgt, indst->in_reserved2);
ISP_IOXGET_8(isp, &insrc->in_status, indst->in_rsvd2);
ISP_IOXGET_8(isp, &insrc->in_rsvd2, indst->in_status);
ISP_IOXGET_8(isp, &insrc->in_tag_val, indst->in_tag_type);
ISP_IOXGET_8(isp, &insrc->in_tag_type, indst->in_tag_val);
} else {
ISP_IOXGET_8(isp, &insrc->in_lun, indst->in_lun);
ISP_IOXGET_8(isp, &insrc->in_iid, indst->in_iid);
ISP_IOXGET_8(isp, &insrc->in_reserved2, indst->in_reserved2);
ISP_IOXGET_8(isp, &insrc->in_tgt, indst->in_tgt);
ISP_IOXGET_8(isp, &insrc->in_status, indst->in_status);
ISP_IOXGET_8(isp, &insrc->in_rsvd2, indst->in_rsvd2);
ISP_IOXGET_8(isp, &insrc->in_tag_val, indst->in_tag_val);
ISP_IOXGET_8(isp, &insrc->in_tag_type, indst->in_tag_type);
}
ISP_IOXGET_32(isp, &insrc->in_flags, indst->in_flags);
ISP_IOXGET_16(isp, &insrc->in_seqid, indst->in_seqid);
for (i = 0; i < IN_MSGLEN; i++) {
ISP_IOXGET_8(isp, &insrc->in_msg[i], indst->in_msg[i]);
}
for (i = 0; i < IN_RSVDLEN; i++) {
ISP_IOXGET_8(isp, &insrc->in_reserved3[i],
indst->in_reserved3[i]);
}
for (i = 0; i < QLTM_SENSELEN; i++) {
ISP_IOXGET_8(isp, &insrc->in_sense[i],
indst->in_sense[i]);
}
}
static INLINE void
isp_put_notify_fc(struct ispsoftc *isp, in_fcentry_t *insrc,
in_fcentry_t *indst)
{
isp_copy_out_hdr(isp, &insrc->in_header, &indst->in_header);
ISP_IOXPUT_32(isp, insrc->in_reserved, &indst->in_reserved);
ISP_IOXPUT_8(isp, insrc->in_lun, &indst->in_lun);
ISP_IOXPUT_8(isp, insrc->in_iid, &indst->in_iid);
ISP_IOXPUT_16(isp, insrc->in_scclun, &indst->in_scclun);
ISP_IOXPUT_32(isp, insrc->in_reserved2, &indst->in_reserved2);
ISP_IOXPUT_16(isp, insrc->in_status, &indst->in_status);
ISP_IOXPUT_16(isp, insrc->in_task_flags, &indst->in_task_flags);
ISP_IOXPUT_16(isp, insrc->in_seqid, &indst->in_seqid);
}
static INLINE void
isp_get_notify_fc(struct ispsoftc *isp, in_fcentry_t *insrc,
in_fcentry_t *indst)
{
isp_copy_in_hdr(isp, &insrc->in_header, &indst->in_header);
ISP_IOXGET_32(isp, &insrc->in_reserved, indst->in_reserved);
ISP_IOXGET_8(isp, &insrc->in_lun, indst->in_lun);
ISP_IOXGET_8(isp, &insrc->in_iid, indst->in_iid);
ISP_IOXGET_16(isp, &insrc->in_scclun, indst->in_scclun);
ISP_IOXGET_32(isp, &insrc->in_reserved2, indst->in_reserved2);
ISP_IOXGET_16(isp, &insrc->in_status, indst->in_status);
ISP_IOXGET_16(isp, &insrc->in_task_flags, indst->in_task_flags);
ISP_IOXGET_16(isp, &insrc->in_seqid, indst->in_seqid);
}
static INLINE void
isp_put_notify_ack(struct ispsoftc *isp, na_entry_t *nasrc, na_entry_t *nadst)
{
int i;
isp_copy_out_hdr(isp, &nasrc->na_header, &nadst->na_header);
ISP_IOXPUT_32(isp, nasrc->na_reserved, &nadst->na_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXPUT_8(isp, nasrc->na_lun, &nadst->na_iid);
ISP_IOXPUT_8(isp, nasrc->na_iid, &nadst->na_lun);
ISP_IOXPUT_8(isp, nasrc->na_status, &nadst->na_event);
ISP_IOXPUT_8(isp, nasrc->na_event, &nadst->na_status);
} else {
ISP_IOXPUT_8(isp, nasrc->na_lun, &nadst->na_lun);
ISP_IOXPUT_8(isp, nasrc->na_iid, &nadst->na_iid);
ISP_IOXPUT_8(isp, nasrc->na_status, &nadst->na_status);
ISP_IOXPUT_8(isp, nasrc->na_event, &nadst->na_event);
}
ISP_IOXPUT_32(isp, nasrc->na_flags, &nadst->na_flags);
for (i = 0; i < NA_RSVDLEN; i++) {
ISP_IOXPUT_16(isp, nasrc->na_reserved3[i],
&nadst->na_reserved3[i]);
}
}
static INLINE void
isp_get_notify_ack(struct ispsoftc *isp, na_entry_t *nasrc, na_entry_t *nadst)
{
int i;
isp_copy_in_hdr(isp, &nasrc->na_header, &nadst->na_header);
ISP_IOXGET_32(isp, &nasrc->na_reserved, nadst->na_reserved);
if (ISP_IS_SBUS(isp)) {
ISP_IOXGET_8(isp, &nasrc->na_lun, nadst->na_iid);
ISP_IOXGET_8(isp, &nasrc->na_iid, nadst->na_lun);
ISP_IOXGET_8(isp, &nasrc->na_status, nadst->na_event);
ISP_IOXGET_8(isp, &nasrc->na_event, nadst->na_status);
} else {
ISP_IOXGET_8(isp, &nasrc->na_lun, nadst->na_lun);
ISP_IOXGET_8(isp, &nasrc->na_iid, nadst->na_iid);
ISP_IOXGET_8(isp, &nasrc->na_status, nadst->na_status);
ISP_IOXGET_8(isp, &nasrc->na_event, nadst->na_event);
}
ISP_IOXGET_32(isp, &nasrc->na_flags, nadst->na_flags);
for (i = 0; i < NA_RSVDLEN; i++) {
ISP_IOXGET_16(isp, &nasrc->na_reserved3[i],
nadst->na_reserved3[i]);
}
}
static INLINE void
isp_put_notify_ack_fc(struct ispsoftc *isp, na_fcentry_t *nasrc,
na_fcentry_t *nadst)
{
int i;
isp_copy_out_hdr(isp, &nasrc->na_header, &nadst->na_header);
ISP_IOXPUT_32(isp, nasrc->na_reserved, &nadst->na_reserved);
ISP_IOXPUT_8(isp, nasrc->na_lun, &nadst->na_lun);
ISP_IOXPUT_8(isp, nasrc->na_iid, &nadst->na_iid);
ISP_IOXPUT_16(isp, nasrc->na_scclun, &nadst->na_scclun);
ISP_IOXPUT_16(isp, nasrc->na_flags, &nadst->na_flags);
ISP_IOXPUT_16(isp, nasrc->na_reserved2, &nadst->na_reserved2);
ISP_IOXPUT_16(isp, nasrc->na_status, &nadst->na_status);
ISP_IOXPUT_16(isp, nasrc->na_task_flags, &nadst->na_task_flags);
ISP_IOXPUT_16(isp, nasrc->na_seqid, &nadst->na_seqid);
for (i = 0; i < NA2_RSVDLEN; i++) {
ISP_IOXPUT_16(isp, nasrc->na_reserved3[i],
&nadst->na_reserved3[i]);
}
}
static INLINE void
isp_get_notify_ack_fc(struct ispsoftc *isp, na_fcentry_t *nasrc,
na_fcentry_t *nadst)
{
int i;
isp_copy_in_hdr(isp, &nasrc->na_header, &nadst->na_header);
ISP_IOXGET_32(isp, &nasrc->na_reserved, nadst->na_reserved);
ISP_IOXGET_8(isp, &nasrc->na_lun, nadst->na_lun);
ISP_IOXGET_8(isp, &nasrc->na_iid, nadst->na_iid);
ISP_IOXGET_16(isp, &nasrc->na_scclun, nadst->na_scclun);
ISP_IOXGET_16(isp, &nasrc->na_flags, nadst->na_flags);
ISP_IOXGET_16(isp, &nasrc->na_reserved2, nadst->na_reserved2);
ISP_IOXGET_16(isp, &nasrc->na_status, nadst->na_status);
ISP_IOXGET_16(isp, &nasrc->na_task_flags, nadst->na_task_flags);
ISP_IOXGET_16(isp, &nasrc->na_seqid, nadst->na_seqid);
for (i = 0; i < NA2_RSVDLEN; i++) {
ISP_IOXGET_16(isp, &nasrc->na_reserved3[i],
nadst->na_reserved3[i]);
}
}
#endif
#endif /* _ISP_INLINE_H */